LECTURE 6: State machines - PowerPoint PPT Presentation

About This Presentation
Title:

LECTURE 6: State machines

Description:

CWRU EECS 317. EECS 317 Computer Design. LECTURE 6: State machines. Instructor: ... Synchronous terminology: Set and Reset. NQ = (R NAND LE) NAND Q; CLR. PS ... – PowerPoint PPT presentation

Number of Views:35
Avg rating:3.0/5.0
Slides: 29
Provided by: francis55
Learn more at: http://bear.ces.cwru.edu
Category:

less

Transcript and Presenter's Notes

Title: LECTURE 6: State machines


1
LECTURE 6 State machines
EECS 317 Computer Design
Instructor Francis G. Wolffwolff_at_eecs.cwru.eduC
ase Western Reserve University This presentation
uses powerpoint animation please viewshow
2
Gated-Clock SR Flip-Flop (Latch Enable)
Q lt (S NAND LE) NAND NQ
S
NQ lt (R NAND LE) NAND Q
Q
LE
Synchronous terminology Set and Reset
Q
R
Asynchronous terminology Preset and Clear
Latches require that during the gated-clock the
data must also be stable (i.e. S and R) at the
same time
Suppose each gate was 5ns how long does the
clock have to be enabled to latch the data?
Answer 15ns
3
Structural SR Flip-Flop (Latch)
ENTITY Latch IS PORT(R, S IN std_logic Q, NQ
OUT std_logic)END ENTITY ARCHITECTURE
latch_arch OF Latch ISBEGIN Q lt R NAND
NQ NQ lt S NAND QEND ARCHITECTURE
4
Inferring Behavioral Latches Asynchronous
ARCHITECTURE Latch2_arch OF Latch
ISBEGIN PROCESS (R, S) BEGIN IF R 0
THEN Q lt 1 NQlt0 ELSIF S0
THEN Q lt 0 NQlt1 END IF END
PROCESSEND ARCHITECTURE
5
Gated-Clock SR Flip-Flop (Latch Enable)
ARCHITECTURE Latch_arch OF GC_Latch IS
BEGIN PROCESS (R, S, LE) BEGIN IF LE1
THEN IF R 0 THEN Q lt 1
NQlt0 ELSIF S0 THEN Q lt 0
NQlt1 END IF END IF END PROCESSEND
ARCHITECTURE
6
Rising-Edge Flip-flop
7
Rising-Edge Flip-flop logic diagram
Do not want to code this up as combin-atorial
logic! Too much work!
8
Inferring D-Flip Flops Synchronous
ARCHITECTURE Dff_arch OF Dff ISBEGIN PROCESS
(Clock) BEGIN IF ClockEVENT AND Clock1
THEN Q lt D END IF END PROCESSEND
ARCHITECTURE
Sensitivity lists contain signals used in
conditionals (i.e. IF)
9
Inferring D-Flip Flops rising_edge
ARCHITECTURE Dff_arch OF Dff IS BEGIN PROCESS
(Clock) BEGIN IF ClockEVENT AND Clock1
THEN Q lt D END IF END PROCESSEND
ARCHITECTURE
ARCHITECTURE dff_arch OF dff IS BEGIN PROCESS
(Clock) BEGIN IF rising_edge(Clock) THEN Q
lt D END IF END PROCESSEND ARCHITECTURE
10
Inferring D-Flip Flops Asynchronous Reset
ARCHITECTURE dff_reset_arch OF dff_reset IS
BEGIN PROCESS (Clock, Reset) BEGIN IF Reset
1 THEN -- Asynchronous Reset Q lt
0 ELSIF rising_edge(Clock) THEN
--Synchronous Q lt D END IF END
PROCESS END ARCHITECTURE
11
Inferring D-Flip Flops Synchronous Reset
PROCESS (Clock, Reset) BEGIN IF
rising_edge(Clock) THEN IF Reset1 THEN Q
lt 0 ELSE Q lt D END IF END IFEND
PROCESS
Synchronous Reset Synchronous FF
PROCESS (Clock, Reset) BEGIN IF Reset1
THEN Q lt 0 ELSIF rising_edge(Clock)
THEN Q lt D END IFEND PROCESS
Asynchronous Reset Synchronous FF
12
D-Flip Flops Asynchronous Reset Preset
PROCESS (Clock, Reset, Preset) BEGIN IF
Reset1 THEN --highest priority Q lt
0 ELSIF Preset1 THEN Q lt 0 ELSIF
rising_edge(Clock) THEN Q lt D END IF END
PROCESS
13
VHDL clock behavioral component
ENTITY clock_driver IS GENERIC (Speed TIME 5
ns) PORT (Clk OUT std_logic)END
ARCHITECTURE clock_driver_arch OF clock_driver
IS SIGNAL Clock std_logic 0 BEGIN Clk lt
Clk XOR 1 after Speed Clock lt Clk END
ARCHITECTURECONFIGURATION clock_driver_cfg OF
clock_driver IS FOR clock_driver_arch END
FOREND CONFIGURATION
14
Synchronous Sequential Circuit
15
Abstraction Finite State Machine
16
FSM Representations
17
Moore Machines
18
Simple Design Example
ENTITY FSM_Parity IS PORT (i1 IN std_logic
o1 OUT std_logic CLK IN std_logic
--Clock RST IN std_logic --Reset ) END
19
State Encoding
State Encoding is sequentially done by VHDL
TYPE FSMStates IS (s1, s2) --s10, s21
SIGNAL State, NextState FSMStates
The non-sequential case requires the
following ATTRIBUTE FSMencode string
ATTRIBUTE FSMencode of FSMStates TYPE IS 1 0
20
Simple Design Example
PROCESS (State, i1) BEGIN CASE State
IS WHEN s1 gt if i11 then NextState lt
s2 else NextState lt s1 end if
WHEN s2 gt if i11 then NextState lt
s1 else NextState lt s2 end if WHEN
OTHERS gt NextState lt NextState
END CASE END PROCESS
21
FSM Controller Current State Process
ARCHITECTURE FSM_Parity_arch OF FSM_Parity IS
TYPE FSMStates IS (s1, s2) SIGNAL State,
NextState FSMStates BEGIN PROCESS (State,
i1) BEGIN CASE State IS WHEN s1 gt if
i11 then NextState lt s2 else
NextState lt s1 end if WHEN s2 gt if
i11 then NextState lt s1
else NextState lt s2 end if WHEN OTHERS gt
NextState lt NextState END CASE END
PROCESS WITH State SELECT o1 lt 0 WHEN
s1, 1 WHEN s2, 1 WHEN OTHERS - -
X, L, W, H, U
22
Alternative less coding
23
FSM controller NextState Process
PROCESS (CLK, RST) BEGIN IF RST'1' THEN
-- Asynchronous Reset State lt s1
ELSIF rising_edge(CLK) THEN State lt
NextState END IF END PROCESS END
ARCHITECTURE CONFIGURATION FSM_Parity_cfg OF
FSM_Parity IS FOR FSM_Parity_arch END FOR END
CONFIGURATION
24
Logic Implementations
Synthesis
25
Coke Machine Example
26
Coke Machine State Diagram
27
Coke Machine Diagram II
28
Assignment 6
a) Write the VHDL synchronous code (no latches!)
and test bench for the coke II machine. Note the
dc_shell synthesis analyze command will tell you
if you inferred latches. Hand code and simulation
using the Unix script command. b) Synthesize the
your design and hand in the logic diagram, Unix
script include cell, area, timing report.
Write a Comment
User Comments (0)
About PowerShow.com